| Autor: |
Schemme, Steffen, Breuer, Janos Lucian, Samsun, Remzi Can, Peters, Ralf, Stolten, Detlef |
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| Zdroj: |
Journal of CO2 Utilization; Oct2018, Vol. 27, p223-237, 15p |
| Abstrakt: |
Highlights • Adaption of higher alcohols synthesis to the Power-to-Fuel concept. • Development of synthesis pathways by adapting known and novel processes. • Selection of most promising synthesis pathways from H 2 /CO 2 towards higher alcohols. • TRL assessment of known and novel synthesis pathways. • Aldol condensation as a preferable pathway in the Power-to-Fuel concept. Abstract To address the pressing challenges of energy security and global warming, the coupling of the energy generation and transport sectors using Power-to-Fuel (PtF) technologies is an attractive strategy. PtF means the synthesis of transport fuels based on CO 2 from industrial exhaust gases and H 2 produced from renewable electricity via electrolysis. This paper provides a comprehensive overview of the synthesis possibilities and potentials of H 2 and CO 2 -based methanol and higher alcohols (C 1 –C 8 ; from methanol up to octanol) as alternative transport fuels by adapting established and novel alcohol synthesis pathways to the PtF concept and assessing their technical maturity using the Technology Readiness Level (TRL) method. A literature review reveals that among the alcohols, methanol, ethanol, 1-/2-/iso-butanol and 1-octanol have the highest relevance for fuel blending. With the aim to give a first impression, we roughly estimated and discussed the production costs depending on the H 2 costs. We estimated the TRL of promising synthesis pathways towards alcohols at 8 for methanol and at 4 for ethanol, 1-butanol and iso-octanol. For 1-octanol, no suitable synthetic pathway is currently known. [ABSTRACT FROM AUTHOR] |
| Databáze: |
Supplemental Index |
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